Imaging system using polarization effects to enhance image quality
Abstract
The quality of images produced by confocal microscopy, and especially scanning laser confocal microscopy, is enhanced especially for images obtained in turbid mediums such as many biological tissue specimens, by reducing speckle from scatterers that exist outside (above and below) the section which is being imaged by utilizing sheared beams, both of which are focused to laterally or vertically offset spots and polarizing the beams to have opposite senses of circular polarization (right and left handed circular polarization). The return light from the section of certain polarization is detected after passing through the confocal aperture of the confocal microscope. Images can be formed using optical coherence detection of the return light. Light from scatterers outside the section of interest, which are illuminated by both of the sheared beams, interfere thereby reducing speckle due to such scatterers, and particularly scatters which are adjacent to the section being imaged. Sheared beams having orthogonal linear polarization, as may be obtained from a Wollaston or Nomarski prism are converted into circularly polarized beams of opposite polarization sense by a quarter wave plate and focused into laterally displaced spot. A Dyson type lens is used to obtain sheared beams which when focused form vertically displaced spots. The optical signals representing reflections from the section are derived by polarizing optics which may either be a polarizing beamsplitter in the incident beam path or a retarder and analyzer. The retarder may be selected to provide different polarization phase shifts of the return light, and with the analyzer, detects the degree of elliptical polarization representing the optical activity and circular dichroism producing the optical signal representing the image.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1. A system for viewing of a section of a medium which receives and returns light both from the section and from sites adjacent to the section that reduces the quality of an image formed from said return light from said section, said system comprising a polarization separator and the polarization retarder, which are disposed successively in the path of the light received by the medium for processing the light said medium receives into light which is polarized generally orthogonally and is incident on said medium at spots spaced from each other, thereby providing interference of light returned from said sites and enabling construction of said image in response to a polarization parameter of said return light.
2. The system of claim 1 wherein means are provided for focusing said light processed by said polarization separator and said retarder into foci at said spots.
3. The system of claim 2 wherein said spots are partially overlapping.
4. The system of claim 3 wherein said focusing means providing said spots is an objective optic and said separation of said foci is about one-quarter (1/4) of the axial resolution of said objective optic.
5. The system of claim 1 wherein said polarization parameter is the degree of rotation of the polarization of said return light from said spots.
6. The system of claim 1 wherein said polarization parameter is a function of the optical activity of the light returned from said spots.
7. The system of claim 6 wherein said optical activity is differential circular dichroism.
8. The system according to claim 1 further comprising a condenser for providing said return light and an objective for focusing said spots, thereby providing a microscope for viewing or construction of an image of said section.
9. The system according to claim 8 wherein said microscope is a confocal microscope having a splitter passing light received by said medium and deflecting said return light to said condenser, a confocal aperture said condenser focusing said return light at said confocal aperture.
10. The system according to claim 1 further comprising a scanner in the path of said light for said spots with respect to said section.
11. The system according to claim 10 wherein said scanner is an X-Y scanner, where X and Y are orthogonal directions along said section, an objective focussing said light at said spots, and said polarization separator, polarization retarder and objective being movable in a Z direction orthogonal to said X and Y directions.
12. The system according to claim 10 wherein said scanner is in the path of said incident and return light.
13. The system according to claim 1 further comprising a laser providing a beam of said light which is incident on said medium with polarization such that said beam is sheared in the same direction as said beam and said spots are spaced in the same direction as said beam.
14. The system according to claim 1 wherein said polarization separator is Dyson type lens having refracting portions which have optical axes oriented in directions transverse to each other.
15. The system according to claim 14 wherein said light received by said medium is provided as polarized light substantially linearly polarized along one of said optical axis.
16. The system according to claim 15 wherein said polarization retarder is an optic providing a phase shift of substantially 90°.
17. The system of claim 1 further comprising polarization responsive optics in the path of said return light for passing, for construction of said image, light having predetermined polarization.
18. The system of claim 17 wherein said polarization responsive optics comprises a polarization beam splitter which transmits said light received by said medium and deflects said return light, which respectively have generally orthogonal polarizations.
19. The system of claim 17 wherein said polarization responsive optics comprises a polarizer and analyzer for passing light with selectable elliptical polarization as the polarization parameter for construction of said image represented by selected optical activity.
20. The system of claim 19 wherein said polarizer is a variable optical phase shifter such that said polarizer and analyzer provide an ellipsometer.
21. The system of claim 1 wherein said polarization is circular polarization in opposite senses.
22. Scanning confocal microscope which comprises a laser providing an incident beam, a beam splitter, a scanner for scanning an image plane in a specimen section and generally orthogonal X-Y direction in said plane, a polarization separator which shears said beam into two beams along a direction along said incident beam, a polarization retarder providing said shear beams of generally orthogonal polarizations, and an objective for focusing said sheared beams at spots spaced in said direction in the vicinity of said image plane and which beams overlap outside the vicinity of said image plane and which beams overlap outside the vicinity of said image plane, a confocal aperture, a photo detector behind said aperture, and optics for focusing return light deflected by said beam splitter at said aperture.
23. The microscope according to claim 22 wherein said separator, retarder, and objective are movable together to in a Z direction, generally orthogonal to said X-Y directions thereby selecting different image planes of said specimen.
24. The microscope of claim 23 wherein said separator is a Dyson type lens.
25. The microscope of claim 23 wherein said beam splitter is a polarizing beam splitter.
26. The microscope of claim 23 wherein said beam splitter is a non-polarizing beam splitter and further comprising ellipsometer optics between said beam splitter and said return light focusing optics.
27. An optical coherence imaging system which comprises a source providing light which is of low coherence, a beam splitter which deflects the light from said source into a reference arm and a sample arm to an image plane in a specimen section, a scanner in said sample arm for scanning said specimen in a generally orthogonal X-Y directions in said plane,, a polarization separator which shears said light into two beams, a polarization retarder providing said sheared beams each with an optical sense of generally orthogonal polarization, an objective having an optical axis for focusing said two beams at spots offset from each other in a direction generally along said axis which beams overlap outside the vicinity of said image plane, a detection arm into which light is directed by said beam splitter from said reference and sample arms, and means for providing images in response to interference of light in said detection arm.
28. The system according to claim 27 wherein said separator, rotator and objective are movable together to in a Z direction, generally orthogonal to said X-Y directions thereby selecting different image planes of said specimen.
29. The system of claim 27 wherein said separator is a Dyson type lens to obtain said spots offset in said direction along said axis.
30. The system of claim 27 wherein said beam splitter is a non-polarizing beam splitter.Cited by (0)
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